An Estimation Model of Section Traffic Parameters Based on Connected ADAS Spatiotemporal Data
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摘要: 交通参数实时获取是道路交通管控的重要基础。针对固定检测器观测范围受限和浮动车数量需求大的问题,研究了1种利用车载ADAS联网数据进行路段交通参数估算的方法。通过分析车载ADAS感知的前向目标参数与交通参数的关系,结合广义交通量定义,并考虑多车道条件下ADAS车辆及其邻近前车的相对运动变化特性,建立了1种非稳态交通条件下的交通参数估算模型。在仿真实验环境下获得定参数据集和验证数据集,完成对模型的参数标定和验证,并探讨时空分辨率和ADAS车辆渗透率对模型估算精度的影响规律。基于实验数据分析,结果表明,时间分辨率降低5 min,所提模型估算误差平均减小3.4%,降低时间分辨率可以提升所提模型的估算精度;空间分辨率降低500 m,流量和密度的估算误差平均减小1.68%,却可能导致速度估算误差平均增加5.19%;ADAS车辆渗透率的增长可以增强估算交通参数和观测交通参数在路段时空区域的契合程度。在ADAS逐渐装车应用的背景下,所提的交通参数估算模型可快速、精准获取路段连续时空范围内的交通量信息。Abstract: Real-time acquisition of traffic parameters is an essential basis for road traffic control. A method for estimating section traffic parameters using the connected ADAS data is studied for the limited observation range of fixed detectors and the great demand for floating vehicles. A traffic parameter-estimation model under unsteady traffic conditions is established by analyzing the relationship between forward target parameters perceived by on-board ADAS and traffic parameters, the definition of generalized traffic volume, and the relative motion characteristics of the ADAS vehicle and its neighboring vehicle in a multi-lane environment. According to the simulation, the calibration data set and the verification data set are obtained to complete the parameter calibration and verification of the model. Also, the paper discusses the influences of time and space resolutions, and ADAS vehicle penetration rates on the estimation accuracy of the model. The analysis shows that when the time resolution is reduced by 5 min, the estimation error is reduced by 3.4% on average; reducing the time resolution can improve the estimation accuracy of the proposed model. When the space resolution is reduced by 500 m, the estimation error of flow and density is reduced by 1.68% on average; however, it may lead to an average increase of 5.19% in speed estimation error. The increased penetration rate of ADAS vehicles can enhance the overall fit between estimated traffic parameters and observed traffic parameters in the time-space area of the road sections. In the context of the gradual application of ADAS, the proposed model of traffic parameter estimation can quickly obtain the traffic volume information in the continuous time-space range of the road sections.
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Key words:
- traffic engineering /
- traffic parameter /
- estimation model /
- ADAS /
- time-space resolution /
- penetration rate
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图 2 不同交通条件下的车辆状态变化
Figure 2. Changes of the vehicle status in different traffic conditions
图 7 修正系数f值的正态分布曲线
Figure 7. Normal distribution curve of correction coefficient f value
图 8 估算交通参数和观测交通参数的时空分布图
Figure 8. Time-space distribution of estimated traffic parameters and observed traffic parameters
表 1 DHW与K和THW与Q数学概念分析
Table 1. Analysis of mathematical concepts of DHW and K, THW and Q
变量 定义 分析 DHW 单个车辆所占据的路段长度(m/veh) 存在概念相关性 K 单位长度内所拥有的车辆数量/(veh/km) THW 单个车辆达到某断面所需要的时间/(s/veh) 存在概念相关性 Q 单位时间内通过某断面的车辆数量/(veh/h) 
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表 2 时空分辨率组别设定
Table 2. Time-space resolution group setting
组别 时间分辨率/min 空间分辨率/m 渗透率 时空区域矩阵 ① 5 500 3, 5, 7, 10, 15 8×12 ② 5 1 000 3, 5, 7, 10, 15 4×12 ③ 10 500 3, 5, 7, 10, 15 8×6 ④ 10 1 000 3, 5, 7, 10, 15 4×6 ⑤ 15 500 3, 5, 7, 10, 15 8×4 ⑥ 15 1 000 3, 5, 7, 10, 15 4×4
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表 3 不同时空分辨率下的修正系数f
Table 3. Correction coefficient f under different time-space resolutions
序号 时间分辨率/min 空间分辨率/m 修正系数f值 1 5 500 2.45 2 5 1 000 4.34 3 10 500 2.50 4 10 1 000 4.56 5 15 500 2.63 6 15 1 000 4.45
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表 4 不同条件下的交通量估计比较
Table 4. Comparison of traffic-parameter estimation under different conditions
时空分辨率 渗透率/% 流量 密度 速度 RMSPE /% EC RMSP /% EC RMSP /% EC 15 17.67 0.992 4 17.87 0.990 4 4.59 0.999 5 10 22.65 0.989 3 19.70 0.989 4 6.03 0.999 1 5 minx500 m 7 25.32 0.985 1 23.81 0.983 4 7.84 0.998 5 5 25.92 0.982 9 26.73 0.977 8 8.17 0.998 4 3 32.40 0.974 8 28.73 0.974 4 14.27 0.994 7 15 16.22 0.992 1 17.77 0.992 6 9.04 0.998 1 10 20.81 0.987 0 19.08 0.990 6 9.31 0.998 0 5 minx1 000 m 7 22.44 0.985 7 19.24 0.990 0 13.41 0.995 9 5 29.07 0.972 0 28.21 0.977 6 17.93 0.992 9 3 28.49 0.974 1 28.90 0.979 5 17.16 0.993 4 15 15.67 0.993 1 16.05 0.993 8 4.20 0.999 6 10 16.88 0.993 7 14.54 0.995 2 4.95 0.999 4 10 minx500 m 7 17.85 0.991 2 17.59 0.991 7 5.25 0.999 3 5 19.16 0.989 3 18.03 0.990 6 5.08 0.999 4 3 25.68 0.982 8 23.85 0.985 1 6.92 0.998 9 15 14.82 0.994 1 14.56 0.995 3 8.77 0.998 2 10 17.82 0.992 0 14.87 0.994 7 8.45 0.998 4 10 minx1 000 m 7 17.67 0.992 6 15.90 0.994 1 10.04 0.997 7 5 20.33 0.989 0 16.94 0.993 4 12.69 0.996 4 3 22.67 0.986 9 21.29 0.990 7 12.46 0.996 4 15 14.59 0.994 7 14.63 0.995 7 3.60 0.999 7 10 14.05 0.995 9 14.86 0.995 6 4.32 0.999 6 15 minx500 m 7 13.07 0.995 5 11.78 0.997 0 4.32 0.999 6 5 17.52 0.990 8 15.65 0.994 0 4.75 0.999 5 3 18.56 0.989 5 15.71 0.993 5 6.22 0.999 1 15 13.64 0.995 9 14.44 0.994 9 7.85 0.998 6 10 11.98 0.996 7 12.86 0.995 6 8.07 0.998 5 15 minx1 000 m 7 12.60 0.996 7 12.53 0.995 9 9.41 0.998 0 5 18.68 0.989 9 19.58 0.988 4 12.71 0.996 4 3 19.02 0.991 5 16.51 0.992 2 11.01 0.997 2
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